Impedance devices for obtaining conductance measurements within luminal organs

ABSTRACT

Impedance devices for obtaining conductance measurements within luminal organs. In at least one embodiment of an impedance device of the present disclosure, the device, comprises an elongated body and an detector positioned upon the elongated body, the detector comprising at least five electrodes and configured to obtain one or more conductance measurements generated using a first arrangement of four of the at least five electrodes and further configured to obtain one or more fluid velocity measurements using a second arrangement of four of the at least five electrodes when the elongated body is positioned within a fluid environment of a mammalian luminal organ, wherein the first arrangement is different from the second arrangement.

PRIORITY

This U.S. patent application is related to, claims the priority benefit of, and is a continuation application of, U.S. patent application Ser. No. 13/282,906, filed Oct. 27, 2011 and issued as U.S. Pat. No. 8,886,301 on Nov. 11, 2014, which is related to, claims the priority benefit of, and is a continuation-in-part application of, U.S. patent application Ser. No. 11/891,981, filed Aug. 14, 2007 and issued as U.S. Pat. No. 8,114,143 on Feb. 14, 2012, which is related to, claims the priority benefit of, and is a divisional application of, U.S. patent application Ser. No. 10/782,149, filed Feb. 19, 2004 and issued as U.S. Pat. No. 7,454,244 on Nov. 18, 2008, which is related to, and claims the priority benefit of, U.S. Provisional Patent Application Ser. No. 60/449,266, filed Feb. 21, 2003, U.S. Provisional Patent Application Ser. No. 60/493,145, filed Aug. 7, 2003, and U.S. Provisional Patent Application Ser. No. 60/502,139, filed Sep. 11, 2003. The contents of each of these applications are hereby incorporated by reference in their entirety into this disclosure.

BACKGROUND

The present disclosure relates generally to medical diagnostics and treatment equipment, including, but not limited to, devices for measuring luminal cross-sectional areas of blood vessels, heart valves and other hollow visceral organs, and methods of using the same.

Coronary Heart Disease

Coronary heart disease is caused by atherosclerotic narrowing of the coronary arteries. It is likely to produce angina pectoris, heart attack or both. Coronary heart disease caused 466,101 deaths in USA in 1997 and is the single leading cause of death in America today. Approximately, 12 million people alive today have a history of heart attack, angina pectoris or both. The break down for males and females is 49% and 51%, respectively. This year, an estimated 1.1 million Americans will have a new or recurrent coronary attack, and more than 40% of the people experiencing these attacks will die as a result. About 225,000 people a year die of coronary attack without being hospitalized. These are sudden deaths caused by cardiac arrest, usually resulting from ventricular fibrillation. More than 400,000 Americans and 800,000 patients world-wide undergo a non-surgical coronary artery interventional procedure each year. Although only introduced in the 1990s, in some laboratories intra-coronary stents are used in 90% of these patients.

Stents increase minimal coronary lumen diameter to a greater degree than percutaneous transluminal coronary angioplasty (PTCA) alone according to the results of two randomized trials using the Palmaz-Schatz stent. These trials compared two initial treatment strategies: stenting alone and PTCA with “stent backup” if needed. In the STRESS trial, there was a significant difference in successful angiographic outcome in favor of stenting (96.1% vs. 89.6%).

Intravascular Ultrasound

Currently intravascular ultrasound is the method of choice to determine the true diameter of the diseased vessel in order to size the stent correctly. The term “vessel,” as used herein, refers generally to any hollow, tubular, or luminal organ. The tomographic orientation of ultrasound enables visualization of the full 360° circumference of the vessel wall and permits direct measurements of lumen dimensions, including minimal and maximal diameter and cross-sectional area. Information from ultrasound is combined with that obtained by angiography. Because of the latticed characteristics of stents, radiographic contrast material can surround the stent, producing an angiographic appearance of a large lumen, even when the stent struts are not in full contact with the vessel wall. A large observational ultrasound study after angio-graphically guided stent deployment revealed an average residual plaque area of 51% in a comparison of minimal stent diameter with reference segment diameter, and incomplete wall apposition was frequently observed. In this cohort, additional balloon inflations resulted in a final average residual plaque area of 34%, even though the final angiographic percent stenosis was negative (20.7%). These investigators used ultrasound to guide deployment.

However, using intravascular ultrasound as mentioned above requires a first step of advancement of an ultrasound catheter and then withdrawal of the ultrasound catheter before coronary angioplasty thereby adding additional time to the stent procedure. Furthermore, it requires an ultrasound machine. This adds significant cost and time and more risk to the procedure.

Aortic Stenosis

Aortic Stenosis (AS) is one of the major reasons for valve replacements in adult. AS occurs when the aortic valve orifice narrows secondary to valve degeneration. The aortic valve area is reduced to one fourth of its normal size before it shows a hemodynamic effect. Because the area of the normal adult valve orifice is typically 3.0 to 4.0 cm², an area 0.75-1.0 cm² is usually not considered severe AS. When stenosis is severe and cardiac output is normal, the mean trans-valvular pressure gradient is generally >50 mmHg. Some patients with severe AS remain asymptomatic, whereas others with only moderate stenosis develop symptoms. Therapeutic decisions, particularly those related to corrective surgery, are based largely on the presence or absence of symptoms.

The natural history of AS in the adult consists of a prolonged latent period in which morbidity and mortality are very low. The rate of progression of the stenotic lesion has been estimated in a variety of hemodynamic studies performed largely in patients with moderate AS. Cardiac catheterization and Doppler echocardiographic studies indicate that some patients exhibit a decrease in valve area of 0.1-0.3 cm² per year; the average rate of change is 0.12 cm² per year. The systolic pressure gradient across the valve may increase by as much as 10 to 15 mmHg per year. However, more than half of the reported patients showed little or no progression over a 3-9 year period. Although it appears that progression of AS can be more rapid in patients with degenerative calcific disease than in those with congenital or rheumatic disease, it is not possible to predict the rate of progression in an individual patient.

Eventually, symptoms of angina, syncope, or heart failure develop after a long latent period, and the outlook changes dramatically. After onset of symptoms, average survival is <2-3 years. Thus, the development of symptoms identifies a critical point in the natural history of AS.

Many asymptomatic patients with severe AS develop symptoms within a few years and require surgery. The incidence of angina, dyspnea, or syncope in asymptomatic patients with Doppler outflow velocities of 4 m/s has been reported to be as high as 38% after 2 years and 79% after 3 years. Therefore, patients with severe AS require careful monitoring for development of symptoms and progressive disease.

Indications for Cardiac Catheterization

In patients with AS, the indications for cardiac catheterization and angiography are to assess the coronary circulation (to confirm the absence of coronary artery disease) and to confirm or clarify the clinical diagnosis of AS severity. If echocardiographic data are typical of severe isolated. AS, coronary angiography may be all that is needed before aortic valve replacement (AVR). Complete left- and right-heart catheterization may be necessary to assess the hemodynamic severity of AS if there is a discrepancy between clinical and echocardiographic data or evidence of associated valvular or congenital disease or pulmonary hypertension.

The pressure gradient across a stenotic valve is related to the valve orifice area and transvalvular flow through Bernoulli's principle. Thus, in the presence of depressed cardiac output, relatively low pressure gradients are frequently obtained in patients with severe AS. On the other hand, during exercise or other high-flow states, systolic gradients can be measured in minimally stenotic valves. For these reasons, complete assessment of AS requires (1) measurement of transvalvular flow, (2) determination of the transvalvular pressure gradient, and (3) calculation of the effective valve area. Careful attention to detail with accurate measurements of pressure and flow is important, especially in patients with low cardiac output or a low transvalvular pressure gradient.

Problems with Current Aortic Valve Area Measurements

Patients with severe AS and low cardiac output are often present with only modest transvalvular pressure gradients (i.e., <30 mmHg). Such patients can be difficult to distinguish from those with low cardiac output and only mild to moderate AS. In both situations, the low-flow state and low pressure gradient contribute to a calculated effective valve area that can meet criteria for severe AS. The standard valve area formula (simplified Hakki formula which is valve area=cardiac output/[pressure gradient]^(1/2)) is less accurate and is known to underestimate the valve area in low-flow states; under such conditions, it should be interpreted with caution. Although valve resistance is less sensitive to flow than valve area, resistance calculations have not been proved to be substantially better than valve area calculations.

In patients with low gradient stenosis and what appears to be moderate to severe AS, it may be useful to determine the transvalvular pressure gradient and calculate valve area and resistance during a baseline state and again during exercise or pharmacological (i.e., dobutamine infusion) stress. Patients who do not have true, anatomically severe stenosis exhibit an increase in the valve area during an increase in cardiac output. In patients with severe AS, these changes may result in a calculated valve area that is higher than the baseline calculation but that remains in the severe range, whereas in patients without severe AS, the calculated valve area will fall outside the severe range with administration of dobutamine and indicate that severe AS is not present.

There are many other limitations in estimating aortic valve area in patients with aortic stenosis using echocardiography and cardiac catheterization. Accurate measurement of the aortic valve area in patients with aortic stenosis can be difficult in the setting of low cardiac output or concomitant aortic or mitral regurgitations. Concomitant aortic regurgitation or low cardiac output can overestimate the severity of aortic stenosis. Furthermore, because of the dependence of aortic valve area calculation on cardiac output, any under or overestimation of cardiac output will cause inaccurate measurement of valve area. This is particularly important in patients with tricuspid regurgitation. Falsely measured aortic valve area could cause inappropriate aortic valve surgery in patients who do not need it.

Other Visceral Organs

Visceral organs such as the gastrointestinal tract and the urinary tract serve to transport luminal contents (fluids) from one end of the organ to the other end or to an absorption site. The esophagus, for example, transports swallowed material from the pharynx to the stomach. Diseases may affect the transport function of the organs by changing the luminal cross-sectional area, the peristalsis generated by muscle, or by changing the tissue components. For example, strictures in the esophagus and urethra constitute a narrowing of the organ where fibrosis of the wall may occur. Strictures and narrowing can be treated with distension, much like the treatment of plaques in the coronary arteries.

BRIEF SUMMARY

The present disclosure provides for various devices and systems for measuring cross-sectional areas and pressure gradients in luminal organs. The present disclosure also comprises a method and apparatus for measuring cross-sectional areas and pressure gradients in luminal organs, such as, for example, blood vessels, heart valves, and other visceral hollow organs.

In at least one embodiment, an exemplary system of the present disclosure comprises an impedance catheter capable of being introduced into a treatment site, a solution delivery source for injecting a solution through the catheter into the treatment site, a constant current source enabling the supply of constant electrical current to the treatment site, and a data acquisition system enabling the measurement of parallel conductance at the treatment site, whereby enabling calculation of cross-sectional area at the treatment site.

In at least one embodiment of an impedance device of the present disclosure, the device, comprises an elongated body and an detector positioned upon the elongated body, the detector comprising at least five electrodes and configured to obtain one or more conductance measurements generated using a first arrangement of four of the at least five electrodes and further configured to obtain one or more fluid velocity measurements using a second arrangement of four of the at least five electrodes when the elongated body is positioned within a fluid environment of a mammalian luminal organ, wherein the first arrangement is different from the second arrangement. In another embodiment, the elongated body is selected from the group consisting of a wire and a catheter. In yet another embodiment, at least three electrodes of the at least five electrodes are capable of excitation to generate an electric field when a current source capable of supplying electrical current to the at least three electrodes is operably coupled thereto, and at least two electrodes of the at least five electrodes are capable of are capable of obtaining one or more luminal organ measurements selected from the group consisting of the one or more conductance measurements and the one or more fluid velocity measurements. In an additional embodiment, when the at least two electrodes are operably connected to a data acquisition and processing system, the data acquisition and processing system is capable of receiving the one or more luminal organ measurements and calculating a cross-sectional area of the luminal organ based in part upon the one or more luminal organ measurements and a known distance between the at least two electrodes.

In at least one embodiment of an impedance device of the present disclosure, the at least five electrodes comprise five electrodes comprising a most distal electrode, an electrode immediately adjacent to the most distal electrode, a most proximal electrode, an electrode immediately adjacent to the most proximal electrode, and a central electrode positioned between the electrode immediately adjacent to the most distal electrode and the electrode immediately adjacent to the most proximal electrode. In an additional embodiment, the first arrangement of electrodes comprises the most distal electrode, the electrode immediately adjacent to the most distal electrode, the central electrode, and the electrode immediately adjacent to the most proximal electrode, wherein the most distal electrode and the electrode immediately adjacent to the most proximal electrode are capable of excitation to generate an electric field, and wherein the electrode immediately adjacent to the most distal electrode and the central electrode are configured to obtain the one or more conductance measurements within the electric field. In yet an additional embodiment, when the elongated body is positioned within a fluid environment of a mammalian luminal organ and when the fluid environment includes an indicator, the most proximal electrode is operable to detect the indicator, and detection of the indicator facilitates activation of the first arrangement of electrodes so that the first arrangement of electrodes can obtain the one or more conductance measurements within the electric field. In another embodiment, one or more cross-sectional areas can be calculated based in part upon the one or more conductance measurements and a known distance between the electrode immediately adjacent to the most distal electrode and the central electrode.

In at least one embodiment of an impedance device of the present disclosure, the second arrangement of electrodes comprises the most distal electrode, the electrode immediately adjacent to the most distal electrode, the central electrode, and the most proximal electrode, wherein the most distal electrode and the most proximal electrode are capable of excitation to generate an electric field, wherein the most distal electrode and the electrode immediately adjacent to the most distal electrode comprise a first fluid velocity detection electrode pair, and wherein the central electrode and the most proximal electrode comprise a second fluid velocity detection pair. In another embodiment, when the elongated body is positioned within the fluid environment and the fluid environment comprises an indicator, movement of the indicator past the first fluid velocity detection electrode pair and the second fluid velocity detection electrode pair allows the first fluid velocity detection electrode pair and the second fluid velocity detection electrode pair to obtain the one or more fluid velocity measurements. In yet another embodiment, the most distal electrode is spaced at or about 4 mm from the an electrode immediately adjacent to the most distal electrode, the electrode immediately adjacent to the most distal electrode is spaced at or about 1 mm from the central electrode, the central electrode is spaced at or about 4 mm from the electrode immediately adjacent to the most proximal electrode, and the electrode immediately adjacent to the most proximal electrode is spaced at or about 8 mm from the most proximal electrode. In an additional embodiment, the most distal electrode is spaced at or about 3 mm from the an electrode immediately adjacent to the most distal electrode, the electrode immediately adjacent to the most distal electrode is spaced at or about 3 mm from the central electrode, and the central electrode is spaced at or about 6 mm from the electrode immediately adjacent to the most proximal electrode.

In at least one embodiment of an impedance device of the present disclosure, the at least five electrodes comprise eight electrodes comprising a most distal electrode, an electrode immediately adjacent to the most distal electrode, a most proximal electrode, an electrode immediately adjacent to the most proximal electrode, a central distal electrode, a central proximal electrode, an electrode immediately adjacent to and distal to the central distal electrode, and an electrode immediately adjacent to and proximal to the central proximal electrode.

In an additional embodiment, the most distal electrode and the central distal electrode are capable of excitation to generate a distal electric field, the electrode immediately adjacent to and distal to the central distal electrode and the electrode immediately adjacent to and proximal to the central proximal electrode are capable of excitation to generate a central electric field, the central proximal electrode and the most proximal electrode are capable of excitation to generate a proximal electric field, the one or more conductance measurements can be obtained within each of the distal electric field, the central electric field, and the proximal electric field, and one or more cross-sectional areas can be calculated based in part upon the one or more conductance measurements and known distances between the electrodes used to generate the distal electric field, the central electric field, and the proximal electric field. In yet an additional embodiment, the second arrangement of electrodes comprises the most distal electrode, the central distal electrode, the central proximal electrode, and the most proximal electrode, wherein the most distal electrode and the central distal electrode comprise a first fluid velocity detection electrode pair, and wherein the central proximal electrode and the most proximal electrode comprise a second fluid velocity detection pair. In another embodiment, when the elongated body is positioned within the fluid environment and the fluid environment comprises an indicator, movement of the indicator past the first fluid velocity detection electrode pair and the second fluid velocity detection electrode pair allows the first fluid velocity detection electrode pair and the second fluid velocity detection electrode pair to obtain the one or more fluid velocity measurements.

In at least one embodiment of an impedance device of the present disclosure, the most distal electrode is spaced at or about 3 mm from the electrode immediately adjacent to the most distal electrode, the electrode immediately adjacent to the most distal electrode is spaced at or about 2 mm from the electrode immediately adjacent to and distal to the central distal electrode, the electrode immediately adjacent to and distal to the central distal electrode is spaced at or about 6 mm from the central distal electrode, the central distal electrode is spaced at or about 2 mm from the central proximal electrode, the central proximal electrode is spaced at or about 6 mm from the electrode immediately adjacent to and proximal to the central proximal electrode, the electrode immediately adjacent to and proximal to the central proximal electrode is spaced at or about 2 mm from the electrode immediately adjacent to the most proximal electrode, and the electrode immediately adjacent to the most proximal electrode is spaced at or about 3 mm from the most proximal electrode. In another embodiment, the device further comprises an inflatable balloon positioned along the longitudinal axis of the elongated body located proximal to the detector, wherein the inflatable balloon is in communication with a lumen defined within the elongated body. In yet another embodiment, the device further comprises a tetrapolar detector positioned upon the elongated body within the balloon, the tetrapolar detector comprising two excitation electrodes and two detection electrodes operable to obtain one or more balloon cross-sectional areas.

In at least one embodiment of an impedance device of the present disclosure, the device comprises an elongated body and an detector positioned upon the elongated body, the detector comprising four electrodes configured to obtain one or more conductance measurements within a luminal organ of at least about 4 mm in diameter, the four electrodes comprising a most distal electrode, an electrode immediately adjacent to the most distal electrode, a most proximal electrode, and an electrode immediately adjacent to the most proximal electrode, wherein the most distal electrode is spaced at or about 3 mm from the an electrode immediately adjacent to the most distal electrode, wherein the electrode immediately adjacent to the most distal electrode is spaced at or about 3 mm from the electrode immediately adjacent to the most proximal electrode, and wherein the electrode immediately adjacent to the most proximal electrode is spaced at or about 6 mm from the most proximal electrode.

In at least one embodiment of a method for using an impedance device to obtain a luminal cross-sectional area measurement and a fluid velocity measurement of the present disclosure, the method comprises the steps of introducing at least part of an impedance device into a luminal organ at a first location, the impedance device comprising an elongated body and a detector positioned upon the elongated body, the detector comprising a most distal electrode, an electrode immediately adjacent to the most distal electrode, a most proximal electrode, an electrode immediately adjacent to the most proximal electrode, and a central electrode positioned between the electrode immediately adjacent to the most distal electrode and the electrode immediately adjacent to the most proximal electrode, applying current to the impedance device using a current source, and obtaining, in either order, (a) one or more conductance measurements by exciting the most distal electrode and the electrode immediately adjacent to the most proximal electrode to generate an electric field and detecting using the electrode immediately adjacent to the most distal electrode and the central electrode within the electric field, wherein one or more cross-sectional areas can be calculated based in part upon the one or more conductance measurements and a known distance between the electrode immediately adjacent to the most distal electrode and the central electrode, and (b) one or more fluid velocity measurements by exciting the most distal electrode and the most proximal electrode are capable of excitation to generate an electric field, wherein the most distal electrode and the electrode immediately adjacent to the most distal electrode comprise a first fluid velocity detection electrode pair, wherein the central electrode and the most proximal electrode comprise a second fluid velocity detection pair, and wherein the first fluid velocity detection electrode pair and the second fluid velocity detection electrode pair are operable obtain the one or more fluid velocity measurements by detecting an indicator positioned within the luminal organ. In another embodiment, the method further comprises the step of implanting a stent within the luminal organ using an inflatable balloon coupled to the impedance device, wherein the stent is positioned upon the inflatable balloon prior to implantation within the luminal organ.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A shows a balloon catheter having impedance measuring electrodes supported in front of the stenting balloon, according to an embodiment of the present disclosure;

FIG. 1B shows a balloon catheter having impedance measuring electrodes within and in front of the balloon, according to an embodiment of the present disclosure;

FIG. 1C shows a catheter having an ultrasound transducer within and in front of balloon, according to an embodiment of the present disclosure;

FIG. 1D shows a catheter without a stenting balloon, according to an embodiment of the present disclosure;

FIG. 1E shows a guide catheter with wire and impedance electrodes, according to an embodiment of the present disclosure;

FIG. 1F shows a catheter with multiple detection electrodes, according to an embodiment of the present disclosure;

FIG. 2A shows a catheter in cross-section proximal to the location of the sensors showing the leads embedded in the material of the probe, according to an embodiment of the present disclosure;

FIG. 2B shows a catheter in cross-section proximal to the location of the sensors showing the leads run in separate lumens, according to an embodiment of the present disclosure;

FIG. 3 is a schematic of one embodiment of the system showing a catheter carrying impedance measuring electrodes connected to the data acquisition equipment and excitation unit for the cross-sectional area measurement, according to an embodiment of the present disclosure;

FIG. 4A shows the detected filtered voltage drop as measured in the blood stream before and after injection of 1.5% NaCl solution, according to an embodiment of the present disclosure;

FIG. 4B shows the peak-to-peak envelope of the detected voltage shown in FIG. 4A, according to an embodiment of the present disclosure;

FIG. 5A shows the detected filtered voltage drop as measured in the blood stream before and after injection of 0.5% NaCl solution, according to an embodiment of the present disclosure;

FIG. 5B shows the peak-to-peak envelope of the detected voltage shown in FIG. 5A, according to an embodiment of the present disclosure;

FIG. 6 shows balloon distension of the lumen of the coronary artery, according to an embodiment of the present disclosure;

FIG. 7A shows balloon distension of a stent into the lumen of the coronary artery, according to an embodiment of the present disclosure;

FIG. 7B shows the voltage recorded by a conductance catheter with a radius of 0.55 mm for various size vessels (vessel radii of 3.1, 2.7, 2.3, 1.9, 1.5 and 0.55 mm for the six curves, respectively) when a 0.5% NaCl bolus is injected into the treatment site, according to an embodiment of the present disclosure;

FIG. 7C shows the voltage recorded by a conductance catheter with a radius of 0.55 mm for various size vessels (vessel radii of 3.1, 2.7, 2.3, 1.9, 1.5 and 0.55 mm for the six curves, respectively) when a 1.5% NaCl bolus is injected into the treatment site, according to an embodiment of the present disclosure;

FIG. 8A shows an exemplary device operable to obtain one or more sizing measurements and one or more fluid velocity measurements, according to an embodiment of the present disclosure;

FIG. 8B shows an exemplary device with a balloon coupled thereto, the device operable to obtain one or more sizing measurements and one or more fluid velocity measurements, according to an embodiment of the present disclosure; and

FIGS. 9A-10B show exemplary devices having various numbers of electrodes and various spacings therebetween, according to exemplary embodiments of the present disclosure.

DETAILED DESCRIPTION

For the purposes of promoting an understanding of the principles of the present disclosure, reference will now be made to the embodiments illustrated in the drawings, and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of this disclosure is thereby intended.

This present disclosure makes accurate measures of the luminal cross-sectional area of organ stenosis within acceptable limits to enable accurate and scientific stent sizing and placement in order to improve clinical outcomes by avoiding under or over deployment and under or over sizing of a stent which can cause acute closure or in-stent re-stenosis. In one embodiment, an angioplasty or stent balloon includes impedance electrodes supported by the catheter in front of the balloon. These electrodes enable the immediate measurement of the cross-sectional area of the vessel during the balloon advancement. This provides a direct measurement of non-stenosed area and allows the selection of the appropriate stent size. In one approach, error due to the loss of current in the wall of the organ and surrounding tissue is corrected by injection of two solutions of NaCl or other solutions with known conductivities. In another embodiment impedance electrodes are located in the center of the balloon in order to deploy the stent to the desired cross-sectional area. These embodiments and procedures substantially improve the accuracy of stenting and the outcome and reduce the cost.

Other embodiments make diagnosis of valve stenosis more accurate and more scientific by providing a direct accurate measurement of cross-sectional area of the valve annulus, independent of the flow conditions through the valve. Other embodiments improve evaluation of cross-sectional area and flow in organs like the gastrointestinal tract and the urinary tract.

Embodiments of the present disclosure overcome the problems associated with determination of the size (cross-sectional area) of luminal organs, such as, for example, in the coronary arteries, carotid, femoral, renal and iliac arteries, aorta, gastrointestinal tract, urethra and ureter. Embodiments also provide methods for registration of acute changes in wall conductance, such as, for example, due to edema or acute damage to the tissue, and for detection of muscle spasms/contractions.

As described below, in one preferred embodiment, there is provided an angioplasty catheter with impedance electrodes near the distal end 19 of the catheter (i.e., in front of the balloon) for immediate measurement of the cross-sectional area of a vessel lumen during balloon advancement. This catheter includes electrodes for accurate detection of organ luminal cross-sectional area and ports for pressure gradient measurements. Hence, it is not necessary to change catheters such as with the current use of intravascular ultrasound. In one preferred embodiment, the catheter provides direct measurement of the non-stenosed area, thereby allowing the selection of an appropriately sized stent. In another embodiment, additional impedance electrodes may be incorporated in the center of the balloon on the catheter in order to deploy the stent to the desired cross-sectional area. The procedures described herein substantially improve the accuracy of stenting and improve the cost and outcome as well.

In another embodiment, the impedance electrodes are embedded within a catheter to measure the valve area directly and independent of cardiac output or pressure drop and therefore minimize errors in the measurement of valve area. Hence, measurements of area are direct and not based on calculations with underlying assumptions. In another embodiment, pressure sensors can be mounted proximal and distal to the impedance electrodes to provide simultaneous pressure gradient recording.

Device and System Embodiments

We designed and build the impedance or conductance catheters illustrated in FIGS. 1A-1F. With reference to the exemplary embodiment shown in FIG. 1A, four wires were threaded through one of the 2 lumens of a 4 Fr catheter. Here, electrodes 26 and 28, are spaced 1 mm apart and form the inner (detection) electrodes. Electrodes 25 and 27 are spaced 4-5 mm from either side of the inner electrodes and form the outer (excitation) electrodes.

In one approach, dimensions of a catheter to be used for any given application depend on the optimization of the potential field using finite element analysis described below. For small organs or in pediatric patients the diameter of the catheter may be as small as 0.3 mm. In large organs the diameter may be significantly larger depending on the results of the optimization based on finite element analysis. The balloon size will typically be sized according to the preferred dimension of the organ after the distension. The balloon may be made of materials, such as, for example, polyethylene, latex, polyestherurethane, or combinations thereof. The thickness of the balloon will typically be on the order of a few microns. The catheter will typically be made of PVC or polyethylene, though other materials may equally well be used. The excitation and detection electrodes typically surround the catheter as ring electrodes but they may also be point electrodes or have other suitable configurations. These electrodes may be made of any conductive material, preferably of platinum iridium or a carbon-coasted surface to avoid fibrin deposits. In the preferred embodiment, the detection electrodes are spaced with 0.5-1 mm between them and with a distance between 4-7 mm to the excitation electrodes on small catheters. The dimensions of the catheter selected for a treatment depend on the size of the vessel and are preferably determined in part on the results of finite element analysis, described below. On large catheters, for use in larger vessels and other visceral hollow organs, the electrode distances may be larger.

Referring to FIGS. 1A, 1B, 1C and 1D, several embodiments of the catheters are illustrated. The catheters shown contain to a varying degree different electrodes, number and optional balloon(s). With reference to the embodiment shown in FIG. 1A, there is shown an impedance catheter 20 with 4 electrodes 25, 26, 27 and 28 placed close to the tip 19 of the catheter. Proximal to these electrodes is an angiography or stenting balloon 30 capable of being used for treating stenosis. Electrodes 25 and 27 are excitation electrodes, while electrodes 26 and 28 are detection electrodes, which allow measurement of cross-sectional area during advancement of the catheter, as described in further detail below. The portion of the catheter 20 within balloon 30 includes an infusion port 35 and a pressure port 36.

The catheter 20 may also advantageously include several miniature pressure transducers (not shown) carried by the catheter or pressure ports for determining the pressure gradient proximal at the site where the cross-sectional area is measured. The pressure is preferably measured inside the balloon and proximal, distal to and at the location of the cross-sectional area measurement, and locations proximal and distal thereto, thereby enabling the measurement of pressure recordings at the site of stenosis and also the measurement of pressure-difference along or near the stenosis. In one embodiment, shown in FIG. 1A, Catheter 20 advantageously includes pressure port 90 and pressure port 91 proximal to or at the site of the cross-sectional measurement for evaluation of pressure gradients. As described below with reference to FIGS. 2A, 2B and 3, in one embodiment, the pressure ports are connected by respective conduits in the catheter 20 to pressure sensors in the data acquisition system 100. Such pressure sensors are well known in the art and include, for example, fiber-optic systems, miniature strain gauges, and perfused low-compliance manometry.

In one embodiment, a fluid-filled silastic pressure-monitoring catheter is connected to a pressure transducer. Luminal pressure can be monitored by a low compliance external pressure transducer coupled to the infusion channel of the catheter. Pressure transducer calibration was carried out by applying 0 and 100 mmHg of pressure by means of a hydrostatic column.

In one embodiment, shown in FIG. 1B, the catheter 39 includes another set of excitation electrodes 40, 41 and detection electrodes 42, 43 located inside the angioplastic or stenting balloon 30 for accurate determination of the balloon cross-sectional area during angioplasty or stent deployment. These electrodes are in addition to electrodes 25, 26, 27 and 28.

In one embodiment, the cross-sectional area may be measured using a two-electrode system. In another embodiment, illustrated in FIG. 1F, several cross-sectional areas can be measured using an array of 5 or more electrodes. Here, the excitation electrodes 51, 52, are used to generate the current while detection electrodes 53, 54, 55, 56 and 57 are used to detect the current at their respective sites.

The tip of the catheter can be straight, curved or with an angle to facilitate insertion into the coronary arteries or other lumens, such as, for example, the biliary tract. The distance between the balloon and the electrodes is usually small, in the 0.5-2 cm range but can be closer or further away, depending on the particular application or treatment involved.

In another embodiment, shown in FIG. 1C the catheter 21 has one or more imaging or recording device, such as, for example, ultrasound transducers 50 for cross-sectional area and wall thickness measurements. As shown in this embodiment, the transducers 50 are located near the distal tip 19 of the catheter 21.

FIG. 1D shows an embodiment of the impedance catheter 22 without an angioplastic or stenting balloon. This catheter also possesses an infusion or injection port 35 located proximal relative to the excitation electrode 25 and pressure port 36.

With reference to the embodiment shown in FIG. 1E, the electrodes 25, 26, 27, 28 can also be built onto a wire 18, such as, for example, a pressure wire, and inserted through a guide catheter 23 where the infusion of bolus can be made through the lumen of the guide catheter 37.

With reference to the embodiments shown in FIGS. 1A, 1B, 1C, 1D, 1E and 1F, the impedance catheter advantageously includes optional ports 35, 36, 37 for suction of contents of the organ or infusion of fluid. The suction/infusion port 35, 36, 37 can be placed as shown with the balloon or elsewhere both proximal or distal to the balloon on the catheter. The fluid inside the balloon can be any biologically compatible conducting fluid. The fluid to inject through the infusion port or ports can be any biologically compatible fluid but the conductivity of the fluid is selected to be different from that of blood (e.g., NaCl).

In another embodiment (not illustrated), the catheter contains an extra channel for insertion of a guide wire to stiffen the flexible catheter during the insertion or data recording. In yet another embodiment (not illustrated), the catheter includes a sensor for measurement of the flow of fluid in the body organ.

System for Determining Cross-Sectional Area and Pressure Gradient

The Operation of the Impedance Catheter 20 is as Follows:

With reference to the embodiment shown in FIG. 1A for electrodes 25, 26, 27, 28, conductance of current flow through the organ lumen and organ wall and surrounding tissue is parallel; i.e.,

$\begin{matrix} {{G\left( {z,t} \right)} = {\frac{{{CSA}\left( {z,t} \right)} \cdot C_{b}}{L\;} + {G_{p}\left( {z,t} \right)}}} & \left\lbrack {1a} \right\rbrack \end{matrix}$

where G_(p)(z,t) is the effective conductance of the structure outside the bodily fluid (organ wall and surrounding tissue), and C_(b) is the specific electrical conductivity of the bodily fluid which for blood generally depends on the temperature, hematocrit and orientation and deformation of blood cells and L is the distance between the detection electrodes. Equation [1] can be rearranged to solve for cross sectional area CSA(t), with a correction factor, α, if the electric field is non-homogeneous, as

$\begin{matrix} {{{CSA}\left( {z,t} \right)} = {\frac{L}{\alpha \; C_{b}}\left\lbrack {{G\left( {z,t} \right)} - {G_{p}\left( {z,t} \right)}} \right\rbrack}} & \left\lbrack {1b} \right\rbrack \end{matrix}$

where α would be equal to 1 if the field were completely homogeneous. The parallel conductance, G_(p), is an offset error that results from current leakage. G_(p) would equal 0 if all of the current were confined to the blood and hence would correspond to the cylindrical model given by Equation [10]. In one approach, finite element analysis is used to properly design the spacing between detection and excitation electrodes relative to the dimensions of the vessel to provide a nearly homogenous field such that a can be considered equal to 1. Our simulations show that a homogenous or substantially homogenous field is provided by (1) the placement of detection electrodes substantially equidistant from the excitation electrodes and (2) maintaining the distance between the detection and excitation electrodes substantially comparable to the vessel diameter. In one approach, a homogeneous field is achieved by taking steps (1) and/or (2) described above so that α is equals 1 in the foregoing analysis.

At any given position, z, along the long axis of organ and at any given time, t, in the cardiac cycle, G_(p) is a constant. Hence, two injections of different concentrations and/or conductivities of NaCl solution give rise to two Equations:

C ₁·CSA(z,t)+L·G _(p)(z,t)=L·G ₁(z,t)  [2]

and

C ₂·CSA(z,t)+L·G _(p)(z,t)=L·G ₂(z,t)  [3]

which can be solved simultaneously for CSA and G_(p) as

$\begin{matrix} {{{{CSA}\left( {z,t} \right)} = {L\frac{\left\lbrack {{G_{2}\left( {z,t} \right)} - {G_{1}\left( {z,t} \right)}} \right\rbrack}{\left\lbrack {C_{2} - C_{1}} \right\rbrack}}}{and}} & \lbrack 4\rbrack \\ {{G_{p}\left( {z,t} \right)} = \frac{\left\lbrack {{C_{2} \cdot {G_{1}\left( {z,t} \right)}} - {C_{1} \cdot {G_{2}\left( {z,t} \right)}}} \right\rbrack}{\left\lbrack {C_{2} - C_{1}} \right\rbrack}} & \lbrack 5\rbrack \end{matrix}$

where subscript “1” and subscript “2” designate any two injections of different NaCl concentrations and/or conductivities. For each injection k, C_(k) gives rise to G_(k) which is measured as the ratio of the root mean square of the current divided by the root mean square of the voltage. The C_(k) is typically determined through in vitro calibration for the various NaCl concentrations and/or conductivities. The concentration of NaCl used is typically on the order of 0.45 to 1.8%. The volume of NaCl solution is typically about 5 ml, but sufficient to displace the entire local vascular blood volume momentarily. The values of CSA(t) and G_(p)(t) can be determined at end-diastole or end-systole (i.e., the minimum and maximum values) or the mean thereof.

Once the CSA and G_(p) of the vessel are determined according to the above embodiment, rearrangement of Equation [1] allows the calculation of the specific electrical conductivity of blood in the presence of blood flow as

$\begin{matrix} {C_{b} = {\frac{L}{{CSA}\left( {z,t} \right)}\left\lbrack {{G\left( {z,t} \right)} - {G_{p}\left( {z,t} \right)}} \right\rbrack}} & \lbrack 6\rbrack \end{matrix}$

In this way, Equation [1b] can be used to calculate the CSA continuously (temporal variation as for example through the cardiac cycle) in the presence of blood.

In one approach, a pull or push through is used to reconstruct the vessel along its length. During a long injection (e.g., 10-15 s), the catheter can be pulled back or pushed forward at constant velocity U. Equation [1b] can be expressed as

$\begin{matrix} {{{CSA}\left( {{U \cdot t},t} \right)} = {\frac{L}{C_{b}}\left\lbrack {{G\left( {{U \cdot t},t} \right)} - {G_{p}\left( {U \cdot \left( {t,t} \right)} \right\rbrack}} \right.}} & \lbrack 7\rbrack \end{matrix}$

where the axial position, z, is the product of catheter velocity, U, and time, t; i.e., z=U·t.

For the two injections, denoted by subscript “1” and subscript “2”, respectively, we can consider different time points T1, T2, etc. such that Equation [7] can be written as

$\begin{matrix} {{{CSA}_{1}\left( {{U \cdot T_{1}},t} \right)} = {\frac{L}{C_{1}}\left\lbrack {{G_{1}\left( {{U \cdot T_{1}},t} \right)} - {G_{p\; 1}\left( {{U \cdot T_{1}},t} \right)}} \right\rbrack}} & \left\lbrack {8a} \right\rbrack \\ {{{{CSA}_{1}\left( {{U \cdot T_{1}},t} \right)} = {\frac{L}{C_{2}}\left\lbrack {{G_{2}\left( {{U \cdot T_{1}},t} \right)} - {G_{p\; 1}\left( {{U \cdot T_{1}},t} \right)}} \right\rbrack}}{and}} & \left\lbrack {8b} \right\rbrack \\ {{{CSA}_{2}\left( {{U \cdot T_{2}},t} \right)} = {\frac{L}{C_{1}}\left\lbrack {{G_{1}\left( {{U \cdot T_{2}},t} \right)} - {G_{p\; 2}\left( {{U \cdot T_{2}},t} \right)}} \right\rbrack}} & \left\lbrack {9a} \right\rbrack \\ {{{CSA}_{2}\left( {{U \cdot T_{2}},t} \right)} = {\frac{L}{C_{2}}\left\lbrack {{G_{2}\left( {{U \cdot T_{2}},t} \right)} - {G_{p\; 2}\left( {{U \cdot T_{2}},t} \right)}} \right\rbrack}} & \left\lbrack {9b} \right\rbrack \end{matrix}$

and so on. Each set of Equations [8a], [8b] and [9a], [9b], etc. can be solved for CSA₁, G_(p1) and CSA₂, G_(p2), respectively. Hence, we can measure the CSA at various time intervals and hence of different positions along the vessel to reconstruct the length of the vessel. In one embodiment, the data on the CSA and parallel conductance as a function of longitudinal position along the vessel can be exported from an electronic spreadsheet, such as, for example, an Excel file, to AutoCAD where the software uses the coordinates to render a 3-Dimensional vessel on the monitor.

For example, in one exemplary approach, the pull back reconstruction was made during a long injection where the catheter was pulled back at constant rate by hand. The catheter was marked along its length such that the pull back was made at 2 mm/sec. Hence, during a 10 second injection, the catheter was pulled back about 2 cm. The data was continuously measured and analyzed at every two second interval; i.e., at every 4 mm. Hence, six different measurements of CSA and G_(p) were made which were used to reconstruction the CSA and G_(p) along the length of the 2 cm segment.

Operation of the Impedance Catheter 39:

With reference to the embodiment shown in FIG. 1B, the voltage difference between the detection electrodes 42 and 43 depends on the magnitude of the current (I) multiplied by the distance (D) between the detection electrodes and divided by the conductivity (C) of the fluid and the cross-sectional area (CSA) of the artery or other organs into which the catheter is introduced. Since the current (I), the distance (L) and the conductivity (C) normally can be regarded as calibration constants, an inverse relationship exists between the voltage difference and the CSA as shown by the following Equations:

$\begin{matrix} {{{\Delta \; V} = \frac{I \cdot L}{C \cdot {CSA}}}{or}} & \left\lbrack {10a} \right\rbrack \\ {{CSA} = \frac{G \cdot L}{C}} & \left\lbrack {10b} \right\rbrack \end{matrix}$

where G is conductance expressed as the ratio of current to voltage (I/ΔV). Equation [10] is identical to Equation [1b] if we neglect the parallel conductance through the vessel wall and surrounding tissue because the balloon material acts as an insulator. This is the cylindrical model on which the conductance method is used.

As described below with reference to FIGS. 2A, 2B, 3, 4 and 5, the excitation and detection electrodes are electrically connected to electrically conductive leads in the catheter for connecting the electrodes to the data acquisition system 100.

FIGS. 2A and 2B illustrate two embodiments 20A and 20B of the catheter in cross-section. Each embodiment has a lumen 60 for inflating and deflating the balloon and a lumen 61 for suction and infusion. The sizes of these lumens can vary in size. The impedance electrode electrical leads 70A are embedded in the material of the catheter in the embodiment in FIG. 2A, whereas the electrode electrical leads 70B are tunneled through a lumen 71 formed within the body of catheter 70B in FIG. 2B.

Pressure conduits for perfusion manometry connect the pressure ports 90, 91 to transducers included in the data acquisition system 100. As shown in FIG. 2A pressure conduits 95A may be formed in 20A. In another embodiment, shown in FIG. 2B, pressure conduits 95B constitute individual conduits within a tunnel 96 formed in catheter 20B. In the embodiment described above where miniature pressure transducers are carried by the catheter, electrical conductors will be substituted for these pressure conduits.

With reference to FIG. 3, in one embodiment, the catheter 20 connects to a data acquisition system 100, to a manual or automatic system 105 for distension of the balloon and to a system 106 for infusion of fluid or suction of blood. The fluid will be heated to 37-39° or equivalent to body temperature with heating unit 107. The impedance planimetry system typically includes a current unit, amplifiers and signal conditioners. The pressure system typically includes amplifiers and signal conditioners. The system can optionally contain signal conditioning equipment for recording of fluid flow in the organ.

In one preferred embodiment, the system is pre-calibrated and the probe is available in a package. Here, the package also preferably contains sterile syringes with the fluids to be injected. The syringes are attached to the machine and after heating of the fluid by the machine and placement of the probe in the organ of interest, the user presses a button that initiates the injection with subsequent computation of the desired parameters. The CSA and parallel conductance and other relevant measures such as distensibility, tension, etc. will typically appear on the display panel in the PC module 160. Here, the user can then remove the stenosis by distension or by placement of a stent.

If more than one CSA is measured, the system can contain a multiplexer unit or a switch between CSA channels. In one embodiment, each CSA measurement will be through separate amplifier units. The same may account for the pressure channels.

In one embodiment, the impedance and pressure data are analog signals which are converted by analog-to-digital converters 150 and transmitted to a computer 160 for on-line display, on-line analysis and storage. In another embodiment, all data handling is done on an entirely analog basis. The analysis advantageously includes software programs for reducing the error due to conductance of current in the organ wall and surrounding tissue and for displaying the 2D or 3D-geometry of the CSA distribution along the length of the vessel along with the pressure gradient. In one embodiment of the software, a finite element approach or a finite difference approach is used to derive the CSA of the organ stenosis taking parameters such as conductivities of the fluid in the organ and of the organ wall and surrounding tissue into consideration. In another embodiment, simpler circuits are used; e.g., based on making two or more injections of different NaCl solutions to vary the resistivity of fluid in the vessel and solving the two simultaneous Equations [2] and [3] for the CSA and parallel conductance (Equations [4] and [5], respectively). In another embodiment, the software contains the code for reducing the error in luminal CSA measurement by analyzing signals during interventions such as infusion of a fluid into the organ or by changing the amplitude or frequency of the current from the current amplifier, which may be a constant current amplifier. The software chosen for a particular application, preferably allows computation of the CSA with only a small error instantly or within acceptable time during the medical procedure.

In one approach, the wall thickness is determined from the parallel conductance for those organs that are surrounded by air or non-conducting tissue. In such cases, the parallel conductance is equal to

$\begin{matrix} {G_{p} = \frac{{CSA}_{w} \cdot C_{w}}{L}} & \left\lbrack {11a} \right\rbrack \end{matrix}$

where CSA_(w) is the wall area of the organ and C_(w) is the electrical conductivity through the wall. This Equation can be solved for the wall CSA_(w) as

$\begin{matrix} {{CSA}_{w} = \frac{G_{p} \cdot L}{C_{w}}} & \left\lbrack {11b} \right\rbrack \end{matrix}$

For a cylindrical organ, the wall thickness, h, can be expressed as

$\begin{matrix} {h = \frac{{CSA}_{w}}{\pi \; D}} & \lbrack 12\rbrack \end{matrix}$

where D is the diameter of the vessel which can be determined from the circular CSA (D=[4CSA/π]^(1/2)).

When the CSA, pressure, wall thickness, and flow data are determined according to the embodiments outlined above, it is possible to compute the compliance (e.g., ΔCSA/ΔP), tension (e.g., P·r, where P and r are the intraluminal pressure and radius of a cylindrical organ), stress (e.g., P·r/h where h is the wall thickness of the cylindrical organ), strain (e.g., (C−C_(d))/C_(d) where C is the inner circumference and C_(d) is the circumference in diastole) and wall shear stress (e.g., 4 μQ/r³ where μ, Q and r are the fluid viscosity, flow rate and radius of the cylindrical organ for a fully developed flow). These quantities can be used in assessing the mechanical characteristics of the system in health and disease.

Method

In one approach, luminal cross-sectional area is measured by introducing a catheter from an exteriorly accessible opening (e.g., mouth, nose or anus for GI applications; or e.g., mouth or nose for airway applications) into the hollow system or targeted luminal organ. For cardiovascular applications, the catheter can be inserted into the organs in various ways; e.g., similar to conventional angioplasty. In one embodiment, an 18 gauge needle is inserted into the femoral artery followed by an introducer. A guide wire is then inserted into the introducer and advanced into the lumen of the femoral artery. A 4 or 5 Fr conductance catheter is then inserted into the femoral artery via wire and the wire is subsequently retracted. The catheter tip containing the conductance electrodes can then be advanced to the region of interest by use of x-ray (i.e., fluoroscopy). In another approach, this methodology is used on small to medium size vessels (e.g., femoral, coronary, carotid, iliac arteries, etc.).

In one approach, a minimum of two injections (with different concentrations and/or conductivities of NaCl) are required to solve for the two unknowns, CSA and G_(p). In another approach, three injections will yield three set of values for CSA and G_(p) (although not necessarily linearly independent), while four injections would yield six set of values. In one approach, at least two solutions (e.g., 0.5% and 1.5% NaCl solutions) are injected in the targeted luminal organ or vessel. Our studies indicate that an infusion rate of approximately 1 ml/s for a five second interval is sufficient to displace the blood volume and results in a local pressure increase of less than 10 mmHg in the coronary artery. This pressure change depends on the injection rate which should be comparable to the organ flow rate.

In one preferred approach, involving the application of Equations [4] and [5], the vessel is under identical or very similar conditions during the two injections. Hence, variables, such as, for example, the infusion rate, bolus temperature, etc., are similar for the two injections. Typically, a short time interval is to be allowed (1-2 minute period) between the two injections to permit the vessel to return to homeostatic state. This can be determined from the baseline conductance as shown in FIG. 4 or 5. The parallel conductance is preferably the same or very similar during the two injections. In one approach, dextran, albumin or another large molecular weight molecule can be added to the NaCl solutions to maintain the colloid osmotic pressure of the solution to reduce or prevent fluid or ion exchange through the vessel wall.

In one approach, the NaCl solution is heated to body temperature prior to injection since the conductivity of current is temperature dependent. In another approach, the injected bolus is at room temperature, but a temperature correction is made since the conductivity is related to temperature in a linear fashion.

In one approach, a sheath is inserted either through the femoral or carotid artery in the direction of flow. To access the lower anterior descending (LAD) artery, the sheath is inserted through the ascending aorta. For the carotid artery, where the diameter is typically on the order of 5-5.5 mm, a catheter having a diameter of 1.9 mm can be used, as determined from finite element analysis, discussed further below. For the femoral and coronary arteries, where the diameter is typically in the range from 3.5-4 mm, so a catheter of about 0.8 mm diameter would be appropriate. The catheter can be inserted into the femoral, carotid or LAD artery through a sheath appropriate for the particular treatment. Measurements for all three vessels can be made similarly.

Described here are the protocol and results for one exemplary approach that is generally applicable to most arterial vessels. The conductance catheter was inserted through the sheath for a particular vessel of interest. A baseline reading of voltage was continuously recorded. Two containers containing 0.5% and 1.5% NaCl were placed in temperature bath and maintained at 37°. A 5-10 ml injection of 1.5% NaCl was made over a 5 second interval. The detection voltage was continuously recorded over a 10 second interval during the 5 second injection. Several minutes later, a similar volume of 1.5% NaCl solution was injected at a similar rate. The data was again recorded. Matlab was used to analyze the data including filtering with high pass and with low cut off frequency (1200 Hz). The data was displayed using Matlab and the mean of the voltage signal during the passage of each respective solution was recorded. The corresponding currents were also measured to yield the conductance (G=I/V). The conductivity of each solution was calibrated with six different tubes of known CSA at body temperature. A model using Equation [10] was fitted to the data to calculate conductivity C. The analysis was carried out in SPSS using the non-linear regression fit. Given C and G for each of the two injections, an excel sheet file was formatted to calculate the CSA and G_(p) as per Equations [4] and [5], respectively. These measurements were repeated several times to determine the reproducibility of the technique. The reproducibility of the data was within 5%. Ultrasound (US) was used to measure the diameter of the vessel simultaneous with our conductance measurements. The detection electrodes were visualized with US and the diameter measurements was made at the center of the detection electrodes. The maximum differences between the conductance and US measurements were within 10%.

FIGS. 4A, 4B, 5A and 5B illustrate voltage measurements in the blood stream in the left carotid artery. Here, the data acquisition had a sampling frequency of 75 KHz, with two channels—the current injected and the detected voltage, respectively. The current injected has a frequency of 5 KH, so the voltage detected, modulated in amplitude by the impedance changing through the bolus injection will have a spectrum in the vicinity of 5 KHz.

With reference to FIG. 4A there is shown a signal processed with a high pass filter with low cut off frequency (1200 Hz). The top and bottom portions 200, 202 show the peak-to-peak envelope detected voltage which is displayed in FIG. 4B (bottom). The initial 7 seconds correspond to the baseline; i.e., electrodes in the blood stream. The next 7 seconds correspond to an injection of hyper-osmotic NaCl solution (1.5% NaCl). It can be seen that the voltage is decreased implying increase conductance (since the injected current is constant). Once the NaCl solution is washed out, the baseline is recovered as can be seen in the last portion of the FIGS. 4A and 4B. FIGS. 5A and 5B show similar data corresponding to 0.5% NaCl solutions.

The voltage signals are ideal since the difference between the baseline and the injected solution is apparent and systematic. Furthermore, the pulsation of vessel diameter can be seen in the 0.5% and 1.5% NaCl injections (FIGS. 4 and 5, respectively). This allows determination of the variation of CSA throughout the cardiac cycle as outline above.

The NaCl solution can be injected by hand or by using a mechanical injector to momentarily displace the entire volume of blood or bodily fluid in the vessel segment of interest. The pressure generated by the injection will not only displace the blood in the antegrade direction (in the direction of blood flow) but also in the retrograde direction (momentarily push the blood backwards). In other visceral organs which may be normally collapsed, the NaCl solution will not displace blood as in the vessels but will merely open the organs and create a flow of the fluid. In one approach, after injection of a first solution into the treatment or measurement site, sensors monitor and confirm baseline of conductance prior to injection of a second solution into the treatment site.

The injections described above are preferably repeated at least once to reduce errors associated with the administration of the injections, such as, for example, where the injection does not completely displace the blood or where there is significant mixing with blood. It will be understood that any bifurcation(s) (with branching angle near 90 degrees) near the targeted luminal organ can cause an overestimation of the calculated CSA. Hence, generally the catheter should be slightly retracted or advanced and the measurement repeated. An additional application with multiple detection electrodes or a pull back or push forward during injection will accomplish the same goal. Here, an array of detection electrodes can be used to minimize or eliminate errors that would result from bifurcations or branching in the measurement or treatment site.

In one approach, error due to the eccentric position of the electrode or other imaging device can be reduced by inflation of a balloon on the catheter. The inflation of balloon during measurement will place the electrodes or other imaging device in the center of the vessel away from the wall. In the case of impedance electrodes, the inflation of balloon can be synchronized with the injection of bolus where the balloon inflation would immediately precede the bolus injection. Our results, however, show that the error due to catheter eccentricity is small.

The CSA predicted by Equation [4] corresponds to the area of the vessel or organ external to the catheter (i.e., CSA of vessel minus CSA of catheter). If the conductivity of the NaCl solutions is determined by calibration from Equation [10] with various tubes of known CSA, then the calibration accounts for the dimension of the catheter and the calculated CSA corresponds to that of the total vessel lumen as desired. In one embodiment, the calibration of the CSA measurement system will be performed at 37° C. by applying 100 mmHg in a solid polyphenolenoxide block with holes of known CSA ranging from 7.065 mm² (3 mm in diameter) to 1017 mm² (36 in mm). If the conductivity of the solutions is obtained from a conductivity meter independent of the catheter, however, then the CSA of the catheter is generally added to the CSA computed from Equation [4] to give the desired total CSA of the vessel.

The signals are generally non-stationary, nonlinear and stochastic. To deal with non-stationary stochastic functions, one can use a number of methods, such as the Spectrogram, the Wavelet's analysis, the Wigner-Ville distribution, the Evolutionary Spectrum, Modal analysis, or preferably the intrinsic model function (IMF) method. The mean or peak-to-peak values can be systematically determined by the aforementioned signal analysis and used in Equation [4] to compute the CSA.

Referring to the embodiment shown in FIG. 6, the angioplasty balloon 30 is shown distended within the coronary artery 150 for the treatment of stenosis. As described above with reference to FIG. 1B, a set of excitation electrodes 40, 41 and detection electrodes 42, 43 are located within the angioplasty balloon 30. In another embodiment, shown in FIG. 7A, the angioplasty balloon 30 is used to distend the stent 160 within blood vessel 150.

For valve area determination, it is not generally feasible to displace the entire volume of the heart. Hence, the conductivity of blood is changed by injection of hypertonic NaCl solution into the pulmonary artery which will transiently change the conductivity of blood. If the measured total conductance is plotted versus blood conductivity on a graph, the extrapolated conductance at zero conductivity corresponds to the parallel conductance. In order to ensure that the two inner electrodes are positioned in the plane of the valve annulus (2-3 mm), in one preferred embodiment, the two pressure sensors 36 are advantageously placed immediately proximal and distal to the detection electrodes (1-2 mm above and below, respectively) or several sets of detection electrodes (see, e.g., FIGS. 1D and 1F). The pressure readings will then indicate the position of the detection electrode relative to the desired site of measurement (aortic valve: aortic-ventricular pressure; mitral valve: left ventricular-atrial pressure; tricuspid valve: right atrial-ventricular pressure; pulmonary valve: right ventricular-pulmonary pressure). The parallel conductance at the site of annulus is generally expected to be small since the annulus consists primarily of collagen which has low electrical conductivity. In another application, a pull back or push forward through the heart chamber will show different conductance due to the change in geometry and parallel conductance. This can be established for normal patients which can then be used to diagnose valvular stensosis.

In one approach, for the esophagus or the urethra, the procedures can conveniently be done by swallowing fluids of known conductances into the esophagus and infusion of fluids of known conductances into the urinary bladder followed by voiding the volume. In another approach, fluids can be swallowed or urine voided followed by measurement of the fluid conductances from samples of the fluid. The latter method can be applied to the ureter where a catheter can be advanced up into the ureter and fluids can either be injected from a proximal port on the probe (will also be applicable in the intestines) or urine production can be increased and samples taken distal in the ureter during passage of the bolus or from the urinary bladder.

In one approach, concomitant with measuring the cross-sectional area and or pressure gradient at the treatment or measurement site, a mechanical stimulus is introduced by way of inflating the balloon or by releasing a stent from the catheter, thereby facilitating flow through the stenosed part of the organ. In another approach, concomitant with measuring the cross-sectional area and or pressure gradient at the treatment site, one or more pharmaceutical substances for diagnosis or treatment of stenosis is injected into the treatment site. For example, in one approach, the injected substance can be smooth muscle agonist or antagonist. In yet another approach, concomitant with measuring the cross-sectional area and or pressure gradient at the treatment site, an inflating fluid is released into the treatment site for release of any stenosis or materials causing stenosis in the organ or treatment site.

Again, it will be noted that the methods, systems, and catheters described herein can be applied to any body lumen or treatment site. For example, the methods, systems, and catheters described herein can be applied to any one of the following exemplary bodily hollow systems: the cardiovascular system including the heart; the digestive system; the respiratory system; the reproductive system; and the urogential tract.

Finite Element Analysis:

In one preferred approach, finite element analysis (FEA) is used to verify the validity of Equations [4] and [5]. There are two major considerations for the model definition: geometry and electrical properties. The general Equation governing the electric scalar potential distribution, V, is given by Poisson's Equation as:

∇·(C∇V)=−I  [13]

where C, I and ∇ are the conductivity, the driving current density and the del operator, respectively. Femlab or any standard finite element packages can be used to compute the nodal voltages using Equation [13]. Once V has been determined, the electric field can be obtained from as E=−∇V.

The FEA allows the determination of the nature of the field and its alteration in response to different electrode distances, distances between driving electrodes, wall thicknesses and wall conductivities. The percentage of total current in the lumen of the vessel (% I) can be used as an index of both leakage and field homogeneity. Hence, the various geometric and electrical material properties can be varied to obtain the optimum design; i.e., minimize the non-homogeneity of the field. Furthermore, we simulated the experimental procedure by injection of the two solutions of NaCl to verify the accuracy of Equation [4]. Finally, we assessed the effect of presence of electrodes and catheter in the lumen of vessel. The error terms representing the changes in measured conductance due to the attraction of the field to the electrodes and the repulsion of the field from the resistive catheter body were quantified.

We solved the Poisson's Equation for the potential field which takes into account the magnitude of the applied current, the location of the current driving and detection electrodes, and the conductivities and geometrical shapes in the model including the vessel wall and surrounding tissue. This analysis suggest that the following conditions are optimal for the cylindrical model: (1) the placement of detection electrodes equidistant from the excitation electrodes; (2) the distance between the current driving electrodes should be much greater than the distance between the voltage sensing electrodes; and (3) the distance between the detection and excitation electrodes is comparable to the vessel diameter or the diameter of the vessel is small relative to the distance between the driving electrodes. If these conditions are satisfied, the equipotential contours more closely resemble straight lines perpendicular to the axis of the catheter and the voltage drop measured at the wall will be nearly identical to that at the center. Since the curvature of the equipotential contours is inversely related to the homogeneity of the electric field, it is possible to optimize the design to minimize the curvature of the field lines. Consequently, in one preferred approach, one or more of conditions (1)-(3) described above are met to increase the accuracy of the cylindrical model.

Theoretically, it is impossible to ensure a completely homogeneous field given the current leakage through the vessel wall into the surrounding tissue. We found that the iso-potential line is not constant as we move out radially along the vessel as stipulated by the cylindrical model. In one embodiment, we consider a catheter with a radius of 0.55 mm whose detected voltage is shown in FIGS. 7B and 7C for two different NaCl solutions (0.5% and 1.5%, respectively). The origin corresponds to the center of the catheter. The first vertical line 220 represents the inner part of the electrode which is wrapped around the catheter and the second vertical line 221 is the outer part of the electrode in contact with the solution (diameter of electrode is approximately 0.25 mm). The six different curves, top to bottom, correspond to six different vessels with radii of 3.1, 2.7, 2.3, 1.9, 1.5 and 0.55 mm, respectively. It can be seen that a “hill” occurs at the detection electrode 220, 221 followed by a fairly uniform plateau in the vessel lumen followed by an exponential decay into the surrounding tissue. Since the potential difference is measured at the detection electrode 220, 221, our simulation generates the “hill” whose value corresponds to the equivalent potential in the vessel as used in Equation [4]. Hence, for each catheter size, we varied the dimension of the vessel such that Equation [4] is exactly satisfied. Consequently, we obtained the optimum catheter size for a given vessel diameter such that the distributive model satisfies the lumped Equations (Equation [4] and [5]). In this way, we can generate a relationship between vessel diameter and catheter diameter such that the error in the CSA measurement is less than 5%. In one embodiment, different diameter catheters are prepackaged and labeled for optimal use in certain size vessel. For example, for vessel dimension in the range of 4-5 mm, 5-7 mm or 7-10 mm, our analysis shows that the optimum diameter catheters will be in the range of 0.91.4, 1.4-2 or 2-4.6 mm, respectively. The clinician can select the appropriate diameter catheter based on the estimated vessel diameter of interest. This decision will be made prior to the procedure and will serve to minimize the error in the determination of lumen CSA.

The present disclosure also includes disclosure of impedance devices and systems having particular electrode spacing, which is used to obtain optimal conductance and/or fluid velocity measurements, as well as devices and systems having a new and unique arrangements of electrodes to facilitate optimal conductance and fluid velocity measurements.

Various devices and systems of the present disclosure having a tetrapolar arrangement of electrodes 25, 26, 27, 28, as shown in FIGS. 1A, 1B, and 1E, for example, may have a particular spacing of electrodes so to facilitate optimal conductance measurements. As referenced above, and in at least one exemplary embodiment, electrodes 26 and 28 are spaced 1 mm apart and form the inner (detection) electrodes, and electrodes 25 and 27 are spaced 4-5 mm from either side of the inner electrodes and form the outer (excitation) electrodes. In at least one specific example, the electrodes have a 4-1-4 spacing arrangement, which is indicative of the spacing (in millimeters) between electrodes 25, 26, 27, 28. For example, and as shown in FIG. 1E, the electrodes, starting from the most distal electrode, are in order of 27, 28, 26, and 25. With the 4-1-4 arrangement (most distal first), at least one exemplary device embodiment of the present disclosure has an electrode spacing of or about 4 mm between electrodes 25 and 26, of or about 1 mm between electrodes 26 and 28, and or of about 4 mm between electrodes 28 and 27. Such a spatial arrangement about a wire embodiment, as shown in FIG. 1E for example, or a catheter embodiment, as shown in FIGS. 1A-1D for example, may be optimal for obtaining conductance (and eventual sizing) measurements within relatively small luminal organs.

Such embodiments, as shown in FIGS. 1A-1E, are referred to tetrapolar embodiments as they each comprise four electrodes in a tetrapolar arrangement (outside of a balloon 30) to facilitate sizing measurements within luminal organs. However, the addition of a fifth electrode, specifically and uniquely placed most proximal to the tetrapolar electrodes, can allow for optimal fluid velocity measurements in addition to sizing measurements as referenced herein. Embodiments of devices and systems of the present disclosure having a five-electrode arrangement, as provided in further detail below, are referred to herein as “pentapolar” embodiments.

An exemplary device of the present disclosure having a pentapolar arrangement of electrodes, and therefore capable of obtaining optimal sizing measurements as well as optimal fluid velocity measurements due to their unique and particular arrangement and operation of electrodes, is shown in FIG. 8A. As shown in FIG. 8A, an exemplary device 300, which may have one or more features of various other devices and systems of the present disclosure, such as catheter 20 shown in FIG. 1A, catheter 39 shown in FIG. 1B, catheter 21 shown in FIG. 1C, catheter 22 shown in FIG. 22, and wire 18 shown in FIG. 1E, for example, comprises an elongated body 302 with various electrodes positioned thereon or therein. Body 302, in various embodiments, may comprise various wires or catheters useful in the medical arts that are configured with an exemplary unique arrangement of electrodes as referenced herein.

As shown in FIG. 8A, an exemplary device 300 of the present comprises five electrodes, namely electrodes 304 (corresponding to electrode “A”), 306 (corresponding to electrode “B”), 308 (corresponding to electrode “C”), 310 (corresponding to electrode “D”), and 312 (corresponding to electrode “E”). Such electrodes, as shown in FIGS. 8A and 8B, may be referred to as a detector 314, whereby detector 314 is operable to obtain sizing measurements as well as fluid velocity measurements. In at least one embodiment, the electrodes of device 300 have a 4-1-4-8 spacing arrangement, which is indicative of the spacing (in millimeters) between electrodes 304, 306, 308, 310, 312. For example, and as shown in FIG. 8A, the electrodes, starting from the most distal electrode, are in order of 304, 306, 308, 310, and 312. With the 4-1-4-8 arrangement (most distal first), at least one exemplary device 300 embodiment of the present disclosure has an electrode spacing of or about 4 mm between electrodes 304 and 306, of or about 1 mm between electrodes 306 and 308, of or about 4 mm between electrodes 308 and 310, and of or about 8 mm between electrodes 310 and 312. This spacing is in reference to at least one embodiment of a device 300 of the present disclosure, noting that said spacing is not arbitrary given the special considerations relating to impedance, as an arbitrary electrode spacing would likely result in a device that either can only obtain conductance measurements with a very high error percentage, or result in a device that cannot effectively obtain a conductance measurement regardless of error.

With respect to electrode 312 in particular, it is noted that in the above-referenced embodiment, electrode 312 is spaced furthest away from its adjacent electrode, namely electrode 310, than any other electrode spacing upon device 300. Such spacing allows an exemplary device 300 of the present disclosure to not only obtain optimal sizing measurements, but optimal velocity measurements as well.

The device 300 embodiment shown in FIG. 8A, and the exemplary catheter and wire embodiments shown in FIGS. 1A-1E, for example, can be used to obtain sizing measurements in a similar fashion. For example, and regarding a device 300 embodiment having a pentapolar arrangement of electrodes, the four most distal electrodes can be used to obtain sizing measurements similar to a device having a tetrapolar arrangement of electrodes. For example, an exemplary device 300 embodiment, such as shown in FIG. 8A, can be used to obtain a sizing measurement within a luminal organ by way of exciting using electrodes A and D (namely electrodes 304 and 310) and detecting using electrodes B and C (namely electrodes 306 and 308), similar to the excitation of electrodes 25 and 27 and the detection using electrodes 26 and 28 as generally referenced herein with respect to various device and system embodiments.

Such a tetrapolar arrangement could also be used to obtain fluid velocity measurements, but there is a clear compromise with respect to spacing and accuracy of the sizing and velocity measurements when using a tetrapolar arrangement of electrodes. For example, one would desire to have the inner detection electrodes (namely electrodes 26 and 28 as shown in FIG. 1A, for example, or electrodes B and C (namely electrodes 306 and 308) as shown in FIG. 8A) be relatively close together to obtain optimal sizing measurements. However, and if using a tetrapolar arrangement of electrodes to measure velocity, one would use electrodes 27 and 28 together and would also use electrodes 25 and 26 together, so that 27&28 and 25&26 act as the two detectors, separated by a distance, to obtain velocity measurements. However, when electrodes 26 and 28 are relatively close together, the effective distance between the two velocity detectors (namely 27&28 and 25&26) is very small, leading to relatively inaccurate or unreliable velocity measurements. If the inner electrodes (electrodes 26 and 28) are spaced further apart so to obtain a more accurate and reliable velocity measurement, the accuracy and reliability of the sizing measurements decreases as the distance between the inner electrodes (used as detectors for sizing) increases past 1 mm, for example.

To overcome this inherent compromise, the present disclosure provides for various devices 300 having a pentapolar arrangement so that four of the five electrodes can be used to obtain optimal sizing measurements, and a different four of the five electrodes can be used to obtain optimal fluid velocity measurements. For example, and using device 300 as shown in FIG. 8A as an example, device 300 could be used to obtain sizing measurements by exciting electrodes A and D and detecting using electrodes B and C. Device 300 could also then be used to obtain velocity measurements by exciting electrodes A and E and by detecting using electrodes A&B and electrodes C&E.

The exemplary 4-1-4-8 configuration referenced herein is an exemplary configuration optimized for sizing and fluid velocity measurements within mammalian luminal organs whereby sizing (such as sizing to identify an appropriately-sized stent, for example) is relatively common. However, for larger luminal organs, a different configuration may be required so that the electrode spacing is sufficient to obtain, for example, a luminal cross-sectional area measurement for a luminal organ larger than a typical mammalian artery, for example. As referenced in at least one embodiment herein, the 4-1-4-8 arrangement correspond to spacings of 4 mm, 1 mm, 4 mm, and 8 mm, and in other embodiments, the 4-1-4-8 arrangement may be indicative of a spacing ratio different than the corresponding millimeters.

Another exemplary embodiment of a device 300 of the present disclosure is shown in FIG. 8B. As shown in FIG. 8B, an exemplary device 300 comprises a body 302 and a balloon 30 positioned thereon proximal to detector 314 so that any gas and/or fluid injected through body 302 into balloon 30 by way of a suction/infusion port 35 will not leak into a patient's body when such a device 300 is positioned therein.

As shown in FIG. 8B, device 500 comprises a second detector 316, wherein detector 316, in at least one embodiment, comprises a tetrapolar arrangement of two excitation electrodes 40, 41 and two detection electrodes 42, 43 located inside balloon 30 for accurate determination of the balloon 30 cross-sectional area during sizing of a valve annulus. Such a tetrapolar arrangement of electrodes (excitation, detection, detection, and excitation, in that order) as shown in FIG. 8B would allow sizing within balloon 30, including the determination of balloon 30 cross-sectional area at various stages of inflation.

As shown in FIG. 8B, device 300 may comprise a catheter (an exemplary body 300), wherein balloon 30 is positioned thereon. In addition, an exemplary embodiment of a device 300, as shown in FIG. 8B, comprises a pressure transducer 48 capable of measuring the pressure of a gas and/or a liquid present within balloon 30. Device 300, in at least one embodiment as referenced herein, also has a suction/infusion port 35 defined within catheter 39 inside balloon 30, whereby suction/infusion port 35 permits the injection of a gas and/or a fluid from a lumen of catheter 39 into balloon 30, and further permits the removal of a gas and/or a fluid from balloon 30 back into catheter 39.

The exemplary embodiments of devices 300 shown in FIGS. 8A and 8B are not intended to be the sole embodiments of said devices 300, as various devices 300 of the present disclosure may comprise additional components as shown in various other figures and described herein. For example, an exemplary system of the present disclosure may comprise a device 300 coupled to one more components shown in FIG. 3 just as catheter 20 shown therein is coupled thereto.

At least one embodiment of an exemplary device 300 of the present disclosure is shown in FIG. 9A. As shown in FIG. 9A, electrodes A, B, C, and D (numbered as electrodes 304, 306, 308, and 310 in the figure) are shown in a 4-1-4 tetrapolar arrangement. The numbers appearing below device 300 in the FIG. 9A represent the spacing between electrodes in millimeters and also identify an approximate 1 mm width of each electrode.

The distance between excitation electrodes would be at least two times (2×) the diameter of the vessel being sized. For example, in a 4-1-4 tetrapolar arrangement of electrodes, and considering that each exemplary electrode itself is approximately 1 mm in diameter, the distance between the two excitation electrodes (electrodes 304 and 310) is 11 mm. This calculation is identified by way of the measurements shown in FIG. 9A, whereby each electrode is shown as having a 1 mm length, and whereby the electrodes are shown in a 4-1-4 tetrapolar arrangement (namely 4 mm, 1 mm, and 4 mm from one another). With such an arrangement and size, vessels of up to about 5 mm in diameter (such as coronary vessels) can be measured, as the distance between excitation electrodes (11 mm) is at least two times the diameter (up to about 5 mm) being measured.

Peripheral vessels, having diameters as large as 10 mm in some instances, would require a different electrode spacing than a 4-1-4 arrangement, as such an arrangement would not obtain accurate measurements within a vessel of that size. For example, if a device 300 having a 4-1-4 tetrapolar arrangement of electrodes were used to size a vessel having a 10 mm diameter, the electric field would form a relative sphere instead of a relative cylindrical shape, resulting in an inaccurate impedance measurement.

Accordingly, an exemplary device 300 of the present disclosure configured to size peripheral vessels is shown in FIG. 9B. As shown in FIG. 9B, electrodes A, B, C, and D (numbered as electrodes 304, 306, 308, and 310 in the figure) are shown in a 5-2-10 tetrapolar arrangement. The numbers appearing below device 300 in the FIG. 9B represent the spacing between electrodes in millimeters and also identify an approximate 1 mm width of each electrode. As shown in FIG. 9B, device 300 has a 5-2-10 tetrapolar arrangement of electrodes, whereby the most distal electrode (electrode 304) is 5 mm from its adjacent detection electrode (electrode 306), the two detection electrodes (electrodes 306 and 308) are 2 mm from one another, and the more proximal detection electrode (electrode 308) is 10 mm from the proximal excitation electrode (electrode 310). In such an arrangement, the distance between the two excitation electrodes 304, 310 is 19 mm, which is calculated by estimating the width of each electrode as 1 mm and adding the 5 mm, 2 mm, and 1 mm spacing to the two detection electrodes 306, 308. With such an arrangement and size, vessels of up to about 9 mm or 10 mm in diameter can be precisely measured.

In general, the further apart the excitation electrodes are positioned from one another, the greater the overall parallel conductance, meaning that more current is lost through the vessel itself. Because of this loss, injected current has a fraction within the lumen and a fraction within the surrounding tissue. Given the separation of excitation electrodes, and to get a proper signal to noise ratio, the detection electrodes are expanded from 1 mm to 2 mm in the 5-2-10 electrode arrangement.

Referring back to coronary vessel sizing (up to about 5 mm in diameter), and as referenced generally above, it is preferred to add a fifth electrode to the tetrapolar arrangement to obtain velocity measurements and effectively decouple sizing from velocity. However, and in attempts to optimize a tetrapolar arrangement of electrodes useful for accurate sizing and velocity measurements, a 3-1-6 tetrapolar arrangement was attempted (instead of 4-1-4), and such an arrangement was not successful in obtaining accurate impedance measurements. However, when a 3-2-6 arrangement was tried, it was successfully able to obtain sizing and velocity measurements.

Another exemplary embodiment of an exemplary device 300 of the present disclosure is shown in FIG. 10A. As shown in FIG. 10A, electrodes A, B, C, and D (numbered as electrodes 304, 306, 308, and 310 in the figure) are shown in a 3-2-6 tetrapolar arrangement. The numbers appearing below device 300 in the FIG. 10A also represent the spacing between electrodes in millimeters, and also identify an approximate 1 mm width of each electrode.

With a 3-2-6 arrangement, for example, velocity measurements may be obtained by measuring using the two distal electrodes (electrodes 304 and 306, 3 mm apart) and the two proximal electrodes (electrodes 308 and 310, 6 mm apart). When a constant voltage is applied to the vessel, a voltage drop would be indicative of a first deflection (the two proximal electrodes) and a second deflection (the two distal electrodes) as a bolus of fluid passes across the electrodes. As the first deflection would be identified when the bolus hits the most proximal electrode (namely electrode D) and the second deflection would be identified when the bolus passes the electrode just proximal to the most distal electrode (namely electrode B), the bolus would pass 9 mm after passing electrode D before passing electrode B, resulting in an accurate velocity determination.

An exemplary device having a 4-1-4-8 pentapolar arrangement of electrodes, as referenced above, would allow a bolus to travel 15 mm between the two trigger velocity measurements. For example, velocity measurements could be obtained in a 4-1-4-8 arrangement by exciting electrodes A and E and by detecting using electrodes A&B and electrodes C&E, as referenced above. The two triggers would be at electrode E and electrode B, so that the bolus would pass 8 mm (the distance between electrodes E and D) plus 1 mm (the size of electrode D) plus 4 mm (the distance between electrodes D and C) plus 1 mm (the size of electrode C) plus 1 mm (the distance between electrodes C and B), for a total of 15 mm. As such, the use of a fifth electrode (electrode E) for velocity measurements effectively decouples the sizing and velocity measurements in a 4-1-4-8 embodiment, and if there is no fifth electrode, a 3-2-6 tetrapolar arrangement of electrodes could be used.

Accordingly, and as referenced above, an exemplary device 300 of the present disclosure comprises an elongated body 302 and a detector 314 positioned upon elongated body 302, wherein detector 302 comprises at least five electrodes and configured to obtain one or more conductance measurements generated using a first arrangement of four of the at least five electrodes and further configured to obtain one or more fluid velocity measurements using a second arrangement of four of the at least five electrodes when elongated body 302 is positioned within a fluid environment of a mammalian luminal organ, wherein the first arrangement is different from the second arrangement. Such an exemplary device may comprise a wire and a catheter having the aforementioned features.

In at least one embodiment, at least three electrodes of the at least five electrodes are capable of excitation to generate an electric field when a current source capable of supplying electrical current to the at least three electrodes is operably coupled thereto, and at least two electrodes of the at least five electrodes are capable of are capable of obtaining one or more luminal organ measurements selected from the group consisting of the one or more conductance measurements and the one or more fluid velocity measurements. In various embodiments, when the at least two electrodes are operably connected to a data acquisition and processing system, the data acquisition and processing system is capable of receiving the one or more luminal organ measurements and calculating a cross-sectional area of the luminal organ based in part upon the one or more luminal organ measurements and a known distance between the at least two electrodes.

With respect to an exemplary device 300 of the present disclosure having five electrodes and not more than five electrodes (which can occur as provided in detail below), said electrodes comprise a most distal electrode (electrode 304), an electrode immediately adjacent to the most distal electrode (electrode 306), a most proximal electrode (electrode 312), an electrode immediately adjacent to the most proximal electrode (electrode 310), and a central electrode positioned between the electrode immediately adjacent to the most distal electrode and the electrode immediately adjacent to the most proximal electrode (electrode 308). In at least one embodiment, the first arrangement of electrodes comprises the most distal electrode (electrode 304), the electrode immediately adjacent to the most distal electrode (electrode 306), the central electrode (electrode 308), and the electrode immediately adjacent to the most proximal electrode (electrode 310), wherein electrode 304 and electrode 310 are capable of excitation to generate an electric field, and wherein electrode 306 and electrode 308 are configured to obtain the one or more conductance measurements within the electric field. In various embodiments, one or more cross-sectional areas can be calculated based in part upon the one or more conductance measurements and a known distance between electrode 306 and electrode 308.

In at least one embodiment of a device 300 of the present disclosure, when body 302 is positioned within a fluid environment of a mammalian luminal organ and wherein when the fluid environment includes an indicator, the most proximal electrode (electrode 312) is operable to detect the indicator, and detection of the indicator facilitates activation of the first arrangement of electrodes so that the first arrangement of electrodes can obtain the one or more conductance measurements within the electric field.

In various embodiments, the second arrangement of electrodes comprises the most distal electrode (electrode 304), the electrode immediately adjacent to the most distal electrode (electrode 306), the central electrode (electrode 308), and the most proximal electrode (electrode 312), wherein electrode 304 and electrode 312 are capable of excitation to generate an electric field, wherein electrode 304 and electrode 306 comprise a first fluid velocity detection electrode pair, and wherein electrode 308 and electrode 312 comprise a second fluid velocity detection pair. In such an embodiment, for example, body 302 is positioned within the fluid environment and wherein the fluid environment comprises an indicator, movement of the indicator past the first fluid velocity detection electrode pair (electrode 304, 306) and the second fluid velocity detection electrode pair (electrodes 308, 312) allows the first fluid velocity detection electrode pair and the second fluid velocity detection electrode pair to obtain the one or more fluid velocity measurements. As referenced herein, the term “indicator” is intended to include a substance or property within a fluid that can be detected by an electrode, such as a salt, a dye, a specific chemical, etc., and is not intended to be limited to any particular detectable substance or property.

Another exemplary embodiment of a device 300 of the present disclosure is shown in FIG. 10B. As shown in FIG. 10B, an octapolar arrangement of electrodes having a 3-2-6-2-6-2-3 spacing arrangement is shown, whereby device 300 is operable to simultaneously obtain three cross-sectional area measurements. In such an embodiment, device 300 could be used to, for example, obtain cross-sectional areas within a vessel proximal to a stenosis, at a stenosis, and distal to a stenosis.

FIG. 10B shows electrodes 304, 306, 308, 310, and 312 (corresponding to electrodes A, B, C, D, and E, respectively) and three additional electrodes 1100, 1102, and 1104 (corresponding to electrodes F, G, and H, respectively), whereby electrodes A-H are in alphabetical order starting from the distal end of device 300 (electrode A) and moving toward the proximal end of device 300 (electrode H). The numbers appearing below device 300 in the FIG. 10B also represent the spacing between electrodes in millimeters, and also identify an approximate 1 mm width of each electrode.

In such an embodiment, a distal sizing measurement can be obtained by exciting electrodes A and D (13 mm apart) and detecting with electrodes B and C (2 mm apart), a central sizing measurement can be obtained by exciting electrodes C and F (16 mm apart) and detecting with electrodes D and E (2 mm apart), and a proximal sizing measurement can be obtained by exciting electrodes E and H (13 mm apart) and detecting with electrodes F and G (2 mm apart). If device 300 is then moved to a different position within the luminal organ, three additional sizing measurements can be obtained simultaneously.

Velocity measurements can also be made using a device 300 having a 3-2-6-2-6-2-3 octapolar spacing arrangement as shown in FIG. 10B. With such an electrode arrangement, for example, velocity measurements may be obtained by exciting with electrodes A and H and measuring using electrodes H and D (electrodes 1104 and 310), providing a 13 mm-15 mm distance between the two deflections to provide an accurate velocity measurement. As referenced above, when a constant voltage is applied to the vessel, a voltage drop would be indicative of a first deflection (the two proximal electrodes) and a second deflection (the two distal electrodes) as a bolus of fluid passes across the electrodes. As the first deflection would be identified when the bolus hits the most proximal electrode (namely electrode H) and the second deflection would be identified when the bolus passes electrode D, resulting in an accurate velocity determination given the spacing between electrodes D and H.

In use, and as referenced above, exemplary devices 300 can be introduced into a luminal organ, and using one or more fluid injections, devices 300 can be used to obtain conductance measurements (useful to determine cross-sectional areas, for example), and also used to determine fluid velocity using the electrode arrangements referenced above.

In such an octapolar electrode arrangement, such as shown in FIG. 10B, the eight electrodes comprise a most distal electrode (electrode 304), an electrode immediately adjacent to the most distal electrode (electrode 306), a most proximal electrode (electrode 1104), an electrode immediately adjacent to the most proximal electrode (electrode 1102), a central distal electrode (electrode 310), a central proximal electrode (electrode 312), an electrode immediately adjacent to and distal to the central distal electrode (electrode 308), and an electrode immediately adjacent to and proximal to the central proximal electrode (electrode 1100). In such an embodiment, the most distal electrode (electrode 304) and the central distal electrode (electrode 310) are capable of excitation to generate a distal electric field, wherein the electrode immediately adjacent to and distal to the central distal electrode (electrode 308) and the electrode immediately adjacent to and proximal to the central proximal electrode (electrode 1100) are capable of excitation to generate a central electric field, wherein the central proximal electrode (electrode 312) and the most proximal electrode (electrode 1104) are capable of excitation to generate a proximal electric field, wherein the one or more conductance measurements can be obtained within each of the distal electric field, the central electric field, and the proximal electric field, and wherein one or more cross-sectional areas can be calculated based in part upon the one or more conductance measurements and known distances between the electrodes used to generate the distal electric field, the central electric field, and the proximal electric field.

In various octapolar device 300 embodiments, the second arrangement of electrodes comprises the most distal electrode, the central distal electrode, the central proximal electrode, and the most proximal electrode, wherein the most distal electrode and the central distal electrode comprise a first fluid velocity detection electrode pair, and wherein the central proximal electrode and the most proximal electrode comprise a second fluid velocity detection pair. In at least one embodiment, when the elongated body is positioned within the fluid environment and wherein the fluid environment comprises an indicator, movement of the indicator past the first fluid velocity detection electrode pair and the second fluid velocity detection electrode pair allows the first fluid velocity detection electrode pair and the second fluid velocity detection electrode pair to obtain the one or more fluid velocity measurements.

Again, it is noted that the various devices, systems, and methods described herein can be applied to any body lumen or treatment site. For example, the devices, systems, and methods described herein can be applied to any one of the following exemplary bodily hollow organs: the cardiovascular system including the heart, the digestive system, the respiratory system, the reproductive system, and the urogenital tract.

While various embodiments of impedance devices for obtaining conductance measurements within luminal organs have been described in considerable detail herein, the embodiments are merely offered by way of non-limiting examples of the disclosure described herein. It will therefore be understood that various changes and modifications may be made, and equivalents may be substituted for elements thereof, without departing from the scope of the disclosure. Indeed, this disclosure is not intended to be exhaustive or to limit the scope of the disclosure.

Further, in describing representative embodiments, the disclosure may have presented a method and/or process as a particular sequence of steps. However, to the extent that the method or process does not rely on the particular order of steps set forth herein, the method or process should not be limited to the particular sequence of steps described. Other sequences of steps may be possible. Therefore, the particular order of the steps disclosed herein should not be construed as limitations of the present disclosure. In addition, disclosure directed to a method and/or process should not be limited to the performance of their steps in the order written. Such sequences may be varied and still remain within the scope of the present disclosure. 

1. An impedance device, comprising: an elongated body; and a detector positioned upon the elongated body, the detector comprising at least four electrodes configured to obtain one or more conductance measurements within a luminal organ of at least 4 mm in diameter, the at least four electrodes comprising at least a most distal electrode, an electrode immediately adjacent to the most distal electrode, a proximal electrode, and an electrode immediately adjacent to the proximal electrode; wherein the most distal electrode is spaced at least 3 mm from the an electrode immediately adjacent to the most distal electrode, wherein the electrode immediately adjacent to the most distal electrode is spaced at least 2 mm from the electrode immediately adjacent to the proximal electrode, and wherein the electrode immediately adjacent to the proximal electrode is spaced at least 6 mm from the proximal electrode.
 2. The impedance device of claim 1, wherein the most distal electrode is spaced at least 5 mm from the an electrode immediately adjacent to the most distal electrode, and wherein the electrode immediately adjacent to the proximal electrode is spaced at least 10 mm from the proximal electrode.
 3. The impedance device of claim 1, wherein the elongated body is selected from the group consisting of a wire and a catheter.
 4. The impedance device of claim 1, wherein the most distal electrode and the proximal electrode are spaced at or about 11 mm from each other.
 5. The impedance device of claim 1, wherein the most distal electrode and the proximal electrode are spaced at or about 18 mm from each other.
 6. The impedance device of claim 1, further comprising: an inflatable balloon positioned along the longitudinal axis of the elongated body located proximal to the detector, wherein the inflatable balloon is in communication with a lumen defined within the elongated body.
 7. The impedance device of claim 6, further comprising: a tetrapolar detector positioned upon the elongated body within the balloon, the tetrapolar detector comprising two excitation electrodes and two detection electrodes operable to obtain one or more balloon cross-sectional areas.
 8. An impedance device, comprising: an elongated body; and a detector positioned upon the elongated body, the detector comprising at least four electrodes configured to obtain one or more conductance measurements within a luminal organ of at least 4 mm in diameter, the at least four electrodes comprising at least a most distal electrode, an electrode immediately adjacent to the most distal electrode, a proximal electrode, and an electrode immediately adjacent to the proximal electrode; wherein the electrode immediately adjacent to the most distal electrode is spaced greater than 1 mm from the electrode immediately adjacent to the proximal electrode.
 9. The impedance device of claim 8, wherein the most distal electrode is spaced at least 3 mm from the an electrode immediately adjacent to the most distal electrode, wherein the electrode immediately adjacent to the most distal electrode is spaced at least 2 mm from the electrode immediately adjacent to the proximal electrode and wherein the electrode immediately adjacent to the proximal electrode is spaced at least 6 mm from the proximal electrode.
 10. The impedance device of claim 8, wherein the most distal electrode is spaced at least 5 mm from the an electrode immediately adjacent to the most distal electrode, wherein the electrode immediately adjacent to the most distal electrode is spaced at least 2 mm from the electrode immediately adjacent to the proximal electrode and wherein the electrode immediately adjacent to the proximal electrode is spaced at least 10 mm from the proximal electrode.
 11. The impedance device of claim 8, further comprising: four additional electrodes positioned upon the elongated body, the four additional electrodes and the at least four electrodes comprising at least eight electrodes, wherein two electrodes of the at least eight electrodes are configured to excite an electric field within a luminal organ, and wherein six electrodes of the at least eight electrodes form three pairs of detection electrodes that are configured to sense the electric field at three locations along the elongated body.
 12. The impedance device of claim 8, further comprising: ten additional electrodes positioned upon the elongated body, the ten additional electrodes and the at least four electrodes comprising at least fourteen electrodes, wherein two electrodes of the at least fourteen electrodes are configured to excite an electric field within a luminal organ, and wherein twelve electrodes of the at least fourteen electrodes form six pairs of detection electrodes that are configured to sense the electric field at six locations along the elongated body.
 13. An impedance device, comprising: an elongated body; and a detector positioned upon the elongated body, the detector comprising at least five electrodes, the at least five electrodes comprising: a most distal electrode, an electrode immediately adjacent to the most distal electrode, a most proximal electrode, an electrode immediately adjacent to the most proximal electrode, and a central electrode positioned between the electrode immediately adjacent to the most distal electrode and the electrode immediately adjacent to the most proximal electrode, wherein the electrode immediately adjacent to the most distal electrode is spaced at least 1 mm from the central electrode; wherein the impedance device is configured to obtain one or more conductance measurements and one of more fluid velocity measurements when the elongated body is positioned within a fluid environment of a mammalian luminal organ.
 14. The impedance device of claim 13, wherein the elongated body is selected from the group consisting of a wire and a catheter.
 15. The impedance device of claim 13, wherein a first arrangement of electrodes comprises the most distal electrode, the electrode immediately adjacent to the most distal electrode, the central electrode, and the electrode immediately adjacent to the most proximal electrode, wherein the most distal electrode and the electrode immediately adjacent to the most proximal electrode are capable of excitation to generate an electric field, and wherein the electrode immediately adjacent to the most distal electrode and the central electrode are configured to obtain the one or more conductance measurements within the electric field.
 16. The impedance device of claim 15, wherein one or more cross-sectional areas can be calculated based in part upon the one or more conductance measurements and a known distance between the electrode immediately adjacent to the most distal electrode and the central electrode.
 17. The impedance device of claim 13, wherein the second arrangement of electrodes comprises the most distal electrode, the electrode immediately adjacent to the most distal electrode, the central electrode, and the most proximal electrode, wherein the most distal electrode and the most proximal electrode are capable of excitation to generate an electric field, wherein the most distal electrode and the electrode immediately adjacent to the most distal electrode comprise a first fluid velocity detection electrode pair, and wherein the central electrode and the most proximal electrode comprise a second fluid velocity detection pair.
 18. The impedance device of claim 13, wherein the most distal electrode is spaced 4 mm from the an electrode immediately adjacent to the most distal electrode, wherein the electrode immediately adjacent to the most distal electrode is spaced 1 mm from the central electrode, wherein the central electrode is spaced 4 mm from the electrode immediately adjacent to the most proximal electrode, and wherein the electrode immediately adjacent to the most proximal electrode is spaced 8 mm from the most proximal electrode.
 19. The impedance device of claim 13, wherein the most distal electrode is spaced 3 mm from the an electrode immediately adjacent to the most distal electrode, wherein the electrode immediately adjacent to the most distal electrode is spaced 2 mm from the central electrode, and wherein the central electrode is spaced 6 mm from the electrode immediately adjacent to the most proximal electrode.
 20. The impedance device of claim 13, wherein the most distal electrode is spaced 5 mm from the an electrode immediately adjacent to the most distal electrode, wherein the electrode immediately adjacent to the most distal electrode is spaced 2 mm from the central electrode, and wherein the central electrode is spaced 10 mm from the electrode immediately adjacent to the most proximal electrode. 